The present invention provides a semiconductor integrated circuit for communication (RF IC) realizing high yield without deteriorating a carrier leak characteristic even when a modulation circuit is formed by using cheep parts with large variations. In a semiconductor integrated circuit (RF IC) including: an input circuit constructed by a differential amplifier circuit and a level shifter, which is provided on the ante stage of a mixer of a differential circuit called a Gilbert Cell; and a modulation circuit that performs modulation by adding an I/Q signal and a carrier wave signal, a calibration circuit for canceling a DC offset in an output of the input circuit is provided.
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1. A semiconductor integrated circuit for communication comprising:
a modulation circuit, including a mixer having differential input terminals and differential output terminals, which is used for generating a transmission signal by mixing a baseband signal for transmission and a carrier wave signal; and
a calibration circuit coupled to the differential input terminals of the modulation circuit; and
a comparator circuit coupled to the differential output terminals of the mixer and the calibration circuit,
wherein the comparator circuit detects a potential difference of the differential outputs of the mixer in a state where potentials at both of the differential input terminals of the modulation circuit are controlled to be equal to each other and the mixer is blocked so that the carrier wave signal is not input, and
wherein the comparator circuit outputs a detection result into the calibration circuit, and
wherein the calibration circuit changes potentials of the differential inputs of the mixer on the basis of the detection result, thereby reducing the potential difference of the differential output terminals.
2. A semiconductor integrated circuit for communication according to
wherein detection of the potential difference and reduction of the potential difference of the differential outputs of the mixer by the calibration circuit are executed in response to a predetermined command supplied from the outside.
3. A semiconductor integrated circuit for communication according to
wherein transmission is performed in the unit of a frame formed of a plurality of time slots which are continuous in time, and detection of the potential difference and reduction of the potential difference of the potential difference of the differential outputs of the mixer by the calibration circuit are executed in a period of preparing transmission of a transmission time slot in the frame.
4. A semiconductor integrated circuit for communication according to
wherein detection of the potential difference of the potential difference of the differential outputs of the mixer by the calibration circuit is performed in a first half of the period of preparing transmission of the transmission time slot, and reduction in the potential difference of the potential difference of the differential outputs of the mixer based on the detection result is performed in a latter half of the transmission preparation period.
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This application is a continuation application of U.S. Ser. No. 11/360,424, filed Feb. 24, 2006 (now U.S. Pat. No. 7,848,716), the content of which is hereby incorporated by reference.
The present application claims priority from Japanese patent application No. 2005-052288 filed on Feb. 28, 2005, the content of which is hereby incorporated by reference into this application.
The present invention relates to a semiconductor integrated circuit for communication having therein a modulation circuit for modulating a carrier wave signal with a transmission baseband signal and, further, to a technique for cancelling a DC offset of a modulation circuit. More particularly, the invention relates to a technique effectively applied to a semiconductor integrated circuit for communication which is mounted on a radio communication system such as a cellular phone having a mode of modulating only a phase component and a mode of modulating a phase component and an amplitude mode.
In a radio communication system such as a cellular phone, a semiconductor integrated circuit for communication (hereinbelow, called an RF IC) is used, which down-converts/up-converts frequencies by mixing a local oscillation signal (carrier wave signal) of high frequencies with a reception signal or a transmission baseband signal by a mixer, modulates a transmission signal, and demodulates a reception signal.
A radio communication system of the GSM (Global System for Mobile Communication) or the like in recent years is being practically used, which has a mode called EDGE (Enhanced Data Rates for GMS Evolution) including not only a GMSK (Gaussian filtered Minimum Shift Keying) modulation mode of modulating a phase component of a carrier wave but also a 3π/8 rotating 8-PSK (Phase Shift Keying) modulation mode of modulating a phase component and an amplitude component of a carrier wave, and which can perform communications while switching the modulation modes. In the EDGE mode, not only phase modulation but also amplitude modulation is performed, so that data communication can be performed at higher speed than the GMSK mode performing only phase modulation.
In recent years, there is a demand for a dual-band cellular phone capable of using not only a signal according to the GSM but also a signal according to the WCDMA (Wideband Code Division Multiple Access) that uses spread spectrum as a multiplex method and uses the QPSK (Quadrature PSK) as a modulation method (Japanese Unexamined Patent Publication No. Hei 11 (1999)-205401).
The inventors of the present invention have examined a semiconductor integrated circuit for communication having therein a modulation circuit constructed by an NPN bipolar transistor and an MOSFET (Metal Oxide Semiconductor Field Effect Transistor) obtained by eliminating a PNP bipolar transistor from a modulation circuit using the PNP bipolar transistor for passing constant current in order to reduce the cost of a semiconductor integrated circuit for communication for a cellular phone having the function of dealing a signal according to the GSM.
As a result, the inventors have found that the modulation circuit using no PNP bipolar transistor has a problem such the characteristic degradation called a carrier leak occurs conspicuously, and the yield deteriorates. The carrier leak is a problem such that a frequency component of a carrier wave is included in a transmission signal due to a DC offset of the modulation circuit.
The carrier leak caused by the DC offset of the modulation circuit will be described hereinbelow.
In the circuit of
The component of the carrier wave is a noise component for the wanted wave. It became evident that if the carrier leak amount as the difference between the wanted wave signal level and the carrier wave signal level is −31 dBc as a specification or less, degradation in the transmission characteristics such as phase accuracy occurs in the case of using the circuit of
The present invention has been achieved in the background as described above, and an object of the invention is to provide a semiconductor integrated circuit (RF IC) for communication realizing high yield without deteriorating the carrier leak characteristic even when a modulation circuit is constructed by using cheap parts with large variations.
As a technique of cancelling the DC offset in the modulation circuit, for example, there is the invention disclosed in Japanese Unexamined Patent Publication (JP-A) No. Hei 11 (1999)-205401. In the invention of JP-A No. 11 (1999)-205401, calibration is performed while sending a predetermined signal from a baseband circuit to a modulation circuit. In contrast, an RF IC of the present invention can perform calibration in itself. The ways of performing the calibration are different from each other. The present invention cannot be easily achieved from the invention of JP-A No. 11-205401.
The above and other objects and novel features of the present invention will become apparent from the description of the specification and the appended drawings.
The outline of a representative one of the inventions disclosed in the specification will be briefly described as follows.
In a semiconductor integrated circuit (RF IC) including: an input circuit constructed by a differential amplifier circuit and a level shifter, which is provided on the ante stage of a mixer of a differential circuit called a Gilbert Cell; and a modulation circuit that performs modulation by adding an I/Q signal (transmission baseband signal) and a carrier wave signal, a calibration circuit for canceling a DC offset in the input circuit is provided. Cancellation of the DC offset in the input circuit is performed just before start of transmission.
Since the DC offset in the input circuit can be cancelled by the above-described means, occurrence of a carrier leak in the mixer at the post stage can be avoided, and degradation of the transmission characteristics can be prevented.
The effect obtained by the representative one of the inventions disclosed in the specification will be briefly described as follows.
According to the present invention, a semiconductor integrated circuit (RF IC) realizing high yield without deteriorating the carrier leak characteristic even when a modulation circuit is constructed by using cheap parts with large variations can be realized.
An embodiment of the present invention will be described by using the drawings.
As shown in
The RF IC 200 is constructed by, roughly, a reception-related circuit RXC, a transmission-related circuit TXC, and a control-related circuit CTC including circuits common to the transmission and reception systems, such as a control circuit and a clock generation circuit other than the reception-related circuit RXC and the transmission-related circuit TXC. Modulation circuits 233a and 233b as objects of the invention are provided for the transmission-related circuit TXC and perform quadrature modulation by mixing an intermediate frequency signal as a carrier wave signal with the I and Q signals supplied from the baseband circuit 300.
First, the modulation circuits 233a and 233b and a calibration circuit 231 for them will be described prior to detailed description of the RF IC 200.
The modulation circuit of the embodiment includes an amplifier (preamplifier) AMP0 in a first stage for amplifying input I and /I signals (or Q and /Q signals), a level shifting circuit DLS for shifting the DC level of the amplified signal, and a mixer circuit MIX taking the form of a differential circuit called a Gilbert circuit. The preamplifier AMP0 and the DC level shifting circuit DLS are formed by circuits as shown in
Specifically, the preamplifier AMP0 is constructed by input differential MOSFETs Q1 and Q2, MOSFETs Q3 and Q4 for constant current connected in series between source terminals of the MOSFETs Q1 and Q2 and power supply voltage terminals Vcc, a resistor R0 connected between the source terminals of the MOSFETs Q1 and Q2, and resistors R1 and R2 connected between drain terminals of the MOSFETs Q1 and Q2 and the ground GND. The preamp AMP0 outputs a signal obtained by amplifying the potential difference between the input I and /I signals (or Q and /Q signals) from the drain terminals of the MOSFETs Q1 and Q2.
The level shifting circuit DLS is constructed by a MOSFET Q5 and NPN type bipolar transistors Q7 and Q9 which are connected in series between the power source voltage terminal Vcc and the ground GND, and a MOS transistor Q6 and NPN type bipolar transistors Q8 and Q10 which are similarly connected in series between the power source voltage terminal Vcc and the ground GND. A connection node between the MOSFETs Q7 and Q9 and a connection node between the MOSFETs Q8 and Q10 are connected to the drain terminals of the input differential MOSFETS Q1 and Q2 of the preamp AMP0 in the ante stage. Each of the transistors Q7 and Q8 is so-called diode-connected that a base and a collector are coupled. The transistors Q5 and Q6, and the transistors Q9 and Q10 operate as the constant current sources when a predetermined voltage is applied to the gate or base. A signal obtained by shifting up the output of the preamplifier AMP0 in the ante stage only by the base-emitter voltage of the bipolar transistor is output from collectors of Q7 and Q8.
As shown in
The mixer circuit MIX in
A mixer circuit on the Q signal side which is not shown outputs, as differential signals, signals including signal components corresponding to the frequency sum and the frequency difference of the Q-in and /Q-in signals and the φIF2 and /φIF2. The signals φIF1 and /φIF1 (φIF2 and /φIF2) are orthogonal signals whose phases are shifted from each other by 90°. As the orthogonal signals, signals of a frequency like 80 MHz generated by dividing the frequency of a high-frequency oscillation signal φRF from a local oscillator 262 by an IF frequency dividing circuit 264, and by further dividing and phase-shifting the resultant signals by a frequency divider and a phase shifter 232 are used.
Further, the modulation circuit of the embodiment is provided with change-over switches S21 and S22 on paths to which the intermediate frequency signals φIF1 and /φIF1 (φIF2 and /φIF2) from the frequency divider and phase shifter 232 are input so that direct current voltages VL and VH can be applied to the bases of the differential transistors Q21, Q22, Q23, and Q24 in the upper stage in place of the signals φIF1 and /φIF1 (φIF2 and /φIF2). As the direct current voltages VL and VH, a voltage which can turn off the transistors Q21 and Q24 and a voltage which can turn on the transistors Q22 and Q23 are selected, and a large current is passed to the transistors Q22 and Q23 in the pairs of differential transistors in the upper stage so that input signals of differential transistors Q11 and Q12 in the lower stage can be amplified.
A resistance Re0 for switching gain and on-off switches S23 and S24 are connected in series between the emitters of the pair of differential transistors Q11 and Q12 in the lower stage. A change-over switch S25 for selectively applying a bias voltage Vbias from a not-shown bias generation circuit or a ground voltage is provided for the base terminals of the transistors Q13 and Q14 for constant current.
On the input side of the amplifier (preamplifier) AMP0 in the first stage provided in the ante stage of the Gilbert Cell type mixer circuit MIX having the configuration as described above, switches S26 and S27 for inputting the input I and /I signals (or Q and /Q signals) and switches S28 and S29 for inputting a predetermined direct current voltage Vmcal in place of the I and Q signals are provided. As the direct current voltage Vmcal, a voltage such as 0.625V which is at the same level as that at the time of normal input of the I and /I signals is selected.
The calibration circuit 231 includes: a comparator CMP detecting a potential difference between differential outputs of the mixer circuit MIX; a control logic CTL for performing calibration by controlling the switches S21 to S29 and the like; a DA converter DAC formed by a plurality of constant current sources I1 to I6 and switches S11 to S16 that selectively combine currents of the constant current sources I1 to I6; a change-over switch S10 for selecting, as an output current of the DA converter DAC, any of differential outputs of the level shift circuit DLS. In the constant current sources I1 to I6, current of the constant current source I1 is the largest, and the constant current sources I1 to I6 are weighted with the n-th power of 2 such that I2 is equal to half of I1, and I3 is equal to half of I2.
The control logic CTL is provided with a register REG for holding a 7-bit control code corresponding to an input value of the DA converter DAC. The bit values of the register REG are sequentially set in accordance with an output of the comparator CMP. The constant current sources I1 to I6 and the switches S11 to S16 in series in the DAC, and the change-over switch S10 are on/off controlled according to the control code which is set in the register REG. Concretely, the change-over switch S10 is controlled by the bit “B0” in the control code in the register REG and the switches S11 to S16 in the DAC are controlled by the bits “B1” to “B6”, respectively. The control logic CTL may be constructed separate from the control logic 260 in
Next, the calibration operation of the modulation circuit of the embodiment will be described with reference to
When the calibration of the modulation circuit starts, first, the control logic CTL holds a control signal IQSW_ON at the low level and sets the switches S26 and S27 into the off state. In a state where input of the I and /I signals and the Q and /Q signals is prohibited, a control signal IQMOD_ON is set to the high level to activate the modulation circuit 233a on the I side and the modulation circuit 233b on the Q side. By a control signal MCAL_ON, the comparator CMP is activated and the switches S28 and S29 are set into the on state. The same direct current voltages Vmcal are applied to differential input terminals of the preamplifier AMP0, so that the offset of the preamplifier and subsequent circuits appears in an output (timing t7 in
Subsequently, a calibration control signal ICAL_ON on the I side is set to the high level, and the switches S21 and S22 are switched to apply the direct current voltages VL and VH in place of the intermediate frequency signals φIF1 and /φIF1 to the differential transistors in the upper stage of the mixer circuit MIX. The switches S23 and S24 are also set to the on state so that the resistor Re0 is connected between the emitter terminals of the differential transistors in the lower stage. As a result, the gain of the mixer circuit MIX is set to be high. The switch S25 of the mixer circuit MIX on the I side is set so that bias voltage Vbias is applied to the bases of the transistors Q13 and Q14 for constant current. The switch S25 of the mixer circuit MIX on the Q side is set so that the ground potential GND is applied to the bases of the transistors Q13 and Q14 for constant current (timing t71 in
After that, the control logic CTL determines the states of the switches S10 to S16 in the DA converters DAC with reference to the output of the comparator CMP. Concretely, first, the control code bits B0 to B6 in the register REG are set to “0” to turn off all of the switches S11 to S16 so that current of the DA converter DAC does not flow from the level shifting circuit DLS. In a state where the switch S10 is connected on the side of the /Iin signal, the output of the comparator CMP is determined.
When it is assumed that an output of the comparator CMP is at high level, the electric potential of the I-in signal in the differential outputs Iin and /Iin of the level shifting circuit DLS is higher. Consequently, the control bit B0 of the register REG corresponding to the switch S10 is set to “1” to change the switch S10 to the opposite Iin signal side. Next, the control bit B1 of the resistor REG corresponding to the switch S11 connected in series to the current source I1 having the largest current among the current sources I1 to I6 of the DAC is set to “1” to turn on the switch S11. By the operation, the output electric potential of the I signal in the differential outputs in the DC level shifting circuit DLS is decreased.
In this state, the output of the comparator CMP is determined again. When it is assumed that the output of the comparator CMP is at the high level, the electric potential of the I signal in the DC level shifting circuit DLS is still higher. Therefore, in a similar manner to the control bit B0, the control bit B1 holds “1” and the switch 11 maintains the on state.
At the next time, the control bit B2 of the resister REG corresponding to the switch S12 connected in series to the current source I2 having the second largest current among the current sources I1 to I6 in the DAC is set to “1” to turn on the switch S12. By the operation, the output electric potential on the I signal side in the differential outputs of the DC level shifting circuit DLS is further decreased.
When it is assumed that the output of the comparator CMP is at the low level in the second determination, it means that the electric potential of the I-in signal in the DC level shifting circuit DLS becomes lower. Therefore, the control bit B2 of the register REG is reset to “0” to set the switch S12 to the off state, and the state of the control bit B2 is held continuously.
After that, the control bits B3 to B6 of the register REG are similarly sequentially set to “1” to turn on the switches S13 to S16. When the output of the comparator CMP is at the high level, the control bit is held at “1”. When the output is at the low level, the control bit is set to “0” and held. By such operations, the states of all the control bits B0 to B6 of the resister REG are set. The electric potential of the I-in signal becomes closer to that of the /I-in signal only by the sum of the switches which are on among the current sources I1 to I6 of the DAC, so that the offset voltage as the potential difference between the Iin signal and the /I-in signal decreases.
In the case where the electric potential on the /I-in signal side is high in the stage of the timing t71 in
At the time point when the setting of the control bit B6 is finished, the control signal ICAL_ON is set to the low level and the calibration of the modulation circuit on the I side is finished (timing t72 in
Next, a calibration control signal QCAL_ON on the Q side is set to the high level to apply the direct current voltages VL and VH to the upper stage of the mixer circuit MIX on the Q side, and the switch S25 in the mixer circuit MIX on the Q side is set so that the bias voltage Vbias is applied to the bases of the transistors Q13 and Q14 for constant current (timing t73 in
Concurrently, the control signal MCAL_ON is set to the low level to turn off the switches S28 and S29 so that the direct current voltage Vmcal is not applied to the modulation circuits 233a and 233b on the I and Q sides. After lapse of predetermined time, the control signal IQSW_ON is set to the high level to turn on the switches S26 and S27 so that each of the I and /I signals and the Q and /Q signals can be input to the preamplifier AMP0 (timing t75 in
In
Next, the flow of the whole mode control including the calibration operation in the RF IC of the embodiment will be described by using the timing chart of
When the power supply of the system is turned on, power supply to the RF IC 200 starts. After turn-on of the power supply, for example, a command “Word 4” that instructs reset of the inside is supplied from the baseband IC 300 to the RF IC 200. By the command, circuits such as the register in the RF IC are reset by the control circuit 260, and the RF IC enters an idle mode (sleep mode in which the RF IC waits for a command) (timing t1 in
When a command “Word 7” including a predetermined bit or code instructing the calibration of VCO is supplied from the baseband IC during the idle mode “Idle”, calibration processing (measurement and storage of frequency) of the RFVCO and TXVCO in the RF IC is performed (timing t2 in
After lapse of proper time after transmission of the measurement start command “Word 7”, the baseband IC sends commands “Word 5” and “Word 6” instructing initial setting (timing t3 in
After completion of the initial setting, a command “Word 1” including frequency information of a channel to be used is supplied from the baseband IC to the RF IC. The control circuit enters a warm-up mode “Warm up” for starting up VCO (timing t4 in
After that, when the command “Word 2” instructing receiving operation is transmitted from the baseband IC, a reception mode “Rx” is set, the reception-related circuit RXC is operated, and a reception signal is amplified and demodulated (timing t5 in
When the reception mode “Rx” is finished, the command “Word 1” including frequency information is supplied from the baseband IC 300 to the RF IC 200, and the control circuit 260 enters again the warm-up mode “Warm up” of starting the VCO (timing t6 in
Subsequently, the command “Word 3” instructing start of the transmission mode is transmitted from the baseband IC 300 to the RF IC 200. When the “Word 3” is received, the control circuit 260 enters the transmission mode, prepares transmission by calibration of the modulation circuits 233a and 233b by the calibration circuit 231 of the embodiment, sets a transmission loop TxPLL to the lock state, and modulates and amplifies a transmission signal (timing t7 in
As described above, the calibration of the modulation circuits 233a and 233b in the RF IC of the foregoing embodiment can be finished in extreme short time. Consequently, the calibration can be executed without slowing transmission operation of GSM or hindering transmission.
Finally, the RF IC 200 in
The reception-related circuit RXC includes: low noise amplifiers 210a, 210b, 210c, and 210d for amplifying reception signals in the frequency bands of the PCS, DCS, and GSM; a frequency divider and phase shifter 211 which divides the frequency of a local oscillation signal φRF generated by an RF oscillator (RFVCO) 262 which will be described later to generates orthogonal signals whose phases are shifted from each other by 90°; mixers 212a and 212b for performing demodulation and down-conversion by mixing the orthogonal signals generated by the frequency divider and phase shifter 211 with reception signals amplified by the low noise amplifiers 210a, 210b, 210c, and 210d; high-gain amplification parts 220A and 220B which amplify the demodulated I, Q signals and output the amplified signals to the baseband circuit 300; and a gain control and calibration circuit 213 for controlling gain of amplifiers in the high-gain amplification parts 220A and 220B and cancelling an input DC offset. The reception-related circuit RXC of the embodiment employs a direct conversion method of converting a reception signal directly to a signal in the frequency band of the baseband.
The control-related circuit CTC includes: the control circuit (control logic) 260 for controlling the whole chip; a reference oscillator (DCXO) 261 for generating an oscillation signal φref as a reference; the radio frequency oscillator (RFVCO) 262 as a local oscillator for generating a radio frequency oscillation signal φRF for converting frequency; the RF synthesizer 263 which constructs a PLL circuit in cooperation with the RF oscillator (RFVCO) 262; the frequency dividing circuit 264 which divides the frequency of the oscillation signal φRF generated by the RFVCO 262, modulates transmission signals, and generates an intermediate frequency signal φIF necessary for up-conversion of the first stage; frequency dividing circuits 265 and 266 for dividing the frequency of the oscillation signals φRF and generating signals necessary for frequency conversion of feedback signals in the PLL circuit for transmission; and mode change-over switches SW1 and SW2.
To the control circuit 260, a clock signal CLK for synchronization, a data signal SDATA, a load enable signal LEN as a control signal are supplied from the baseband circuit 300. When the load enable signal LEN is asserted to a valid level, the control circuit 260 sequentially receives the data signal SDATA transmitted from the baseband circuit 300 synchronously with the clock signal CLK and generates a control signal in the chip in accordance with a command included in the data signal SDATA. Although not limited, the data signals SDATA are transmitted in series.
The transmission-related circuit TXC includes: the frequency divider and phase shifter 232 for further dividing the intermediate frequency signal φIF of 160 MHz or the like generated by dividing the frequency of the oscillation signal φRF generated by the RFVCO 262 by the frequency dividing circuit, thereby generating orthogonal signals whose phases are shifted from each other by 90°; the modulation circuits 233a and 233b for modulating the generated orthogonal signals with the I and Q signals supplied from the baseband circuit 300; an adder 234 for adding the modulated signals; a transmission oscillator (TXVCO) 240 for generating a transmission signal φTX of a predetermined frequency; a down-convert mixer 235 for mixing a feedback signal obtained by extracting a transmission signal φTX output from the transmission oscillator (TXVCO) 240 by couplers 280a and 280b and the like and attenuating the signal by an attenuator ATT with a signal φRF′ obtained by frequency-dividing the radio frequency oscillation signal φRF generated by the RF oscillator (RFVCO) 262, thereby generating a signal of a frequency corresponding to the frequency difference between the signals; a phase detector 236 for detecting the phase difference by comparing an output of the mixer 235 with a signal TXIF obtained by addition of the adder 234; a loop filter 237 for generating a voltage according to an output of the phase detector 236; a frequency divider 238 for frequency-dividing an output of the transmission oscillator (TXVCO) 240, thereby generating a GSM transmission signal; and buffer circuits 239a and 239b for transmission output.
The transmission-related circuit of the embodiment employs an offset PLL method of orthogonal-modulating transmission I and Q signals with an intermediate-frequency carrier wave, mixing a feedback signal from the output side of the TXVCO 240 with the signal φRF′ obtained by frequency-dividing the RF oscillation signal φRF of the RFVCO 262, thereby down-converting the I, Q signals to a signal of an intermediate frequency corresponding to the frequency difference and, after that, comparing the phase of the resultant signal with the phase of the signal subjected to the orthogonal modulation, thereby controlling the TXVCO 240 in accordance with the phase difference. An output of the down-convert mixer 235 is supplied to the phase comparator 236 through a path in the GSM mode of GMSK modulation and a path in the EDGE mode of 8 PSK modulation, which are different from each other.
To switch the paths, switches SW3 and SW4 are provided. For the signal path in the GSM mode, a buffer BFF1, a low-pass filter SLPF1, and a buffer BFF2 are provided. For the signal path in the EDGE mode, a variable gain amplifier MVGA, a low-pass filter MLPF2, a limiter LIM2, and a low-pass filter LPF3 are provided. To supply the output of the down-convert mixer 235 via any of the path in the GSM mode of the GMSK modulation and the path in the EDGE mode of the 8 PSK modulation to the phase detector 236, a switch SW5 is provided which switches the paths for supplying a transmission signal of an intermediate frequency obtained by adding signals subjected to orthogonal modulation in the mixers 233a and 233b by the adder 234. In the EDGE mode, the transmission signal is supplied to the phase detector 236 via a limiter LIM1 and a low-pass filter LFP4.
Further, the transmission-related circuit TXC of the embodiment has an amplitude control loop including: an amplitude comparing circuit 244 for detecting the amplitude difference by comparing the output of the down-convert mixer 235 with the transmission signal obtained by adding signals orthogonal-modulated by the mixers 233a and 233b by the adder 234 in order to perform amplitude control in the EDGE mode; a loop filter 245 for band-limiting the output of the amplitude comparing circuit 244; a variable gain amplifier (IVGA) 246 for amplifying the band-limited signal; a voltage-current converting circuit 247 for converting the amplified voltage of the amplitude control loop into current; a level shifting circuit 248; and a filter 249 for converting the current to a voltage. The transmission-related circuit TXC is constructed so that amplitude modulation can be performed in parallel with phase modulation.
Next, a configuration example of the transmission-related circuit in the RF IC as a component of a system capable of performing radio communication in the WCDMA using the modulation circuit having the DC offset calibration circuit will be described with reference to the
The transmission-related circuit of the embodiment includes: an oscillator 267 for generating a local oscillation signal φTXL0 for transmission; a frequency divider 268 for dividing the frequency of the generated oscillation signal φTXL0; the frequency divider and phase shifter 232 for dividing the frequency of the oscillation signal φTXL0 or the signal subjected to the frequency division in the frequency divider 268 to generate orthogonal signals whose phases are shifted from each other by 90°; a buffer BFF for buffering the frequency-divided and phase-shifted signal; amplifiers 230a and 230b for amplifying I and Q signals input from the baseband circuit; low-pass filters LPFa and LPFb for removing higher harmonics; the modulators 233a and 233b for adding the signals transmitted from the frequency divider and phase shifter 232 and the input I and Q signals, and concurrently performing orthogonal modulation and up-conversion; the calibration circuit 231 for canceling a DC offset in the modulators 233a and 233b; and linear variable amplifiers RFVGA1, RFVGA2, and RFVGA3 for amplifying the modulated signal in accordance with an output level instruction signal Vct1 supplied from the baseband circuit.
The modulators 233a and 233b are formed as modulation circuits of a direct up-conversion type capable of converting the I and Q signals in the frequency band of the base band directly into signals in the transmission frequency. The transmission-related circuit of the embodiment is constructed as a triple-band transmission-related circuit capable of handling a 1920-1980 MHz band (band 1), a 1850-1910 MHz band (band2), and a 824-849 MHz band (band 5).
Therefore, the oscillator 267 for generating the local oscillation signal φTXL0 generates the oscillation signal φTXL0 of 3840-3960 MHz, 3700-3820 MHz, and 3296-3396 MHz in accordance with the bands. In the band 5 of low frequencies, a switch SW bypassing the frequency divider 268 is turned off, the frequency of the signal φTXL0 is divided by four, and the resultant signals are supplied to the modulators 233a and 233b. In the bands 1 and 2 of high frequencies, the switch SW is turned on to make the signal φTXL0 bypass the frequency divider 268, the frequency of the signal φTXL0 is divided by two, and the resultant signals are supplied to the modulators 233a and 233b.
In the GSMA, as described above, for example, a circuit may be constructed so that calibration is performed on the basis of a command instructing start of transmission. In this case, as shown in
Although the present invention achieved by the inventors herein has been described concretely on the basis of the embodiment, the invention is not limited to the foregoing embodiment. For example, a temperature detection circuit 270 may be provided as shown by the broken line in
In the embodiment of
In the above description, the present invention achieved by the inventors herein is applied to the modulation circuit for transmission in the RF IC used for a radio communication system such as a cellular phone in the field of utilization as the background of the invention. However, the invention is not limited to the embodiment but can be also applied to not only the RF IC for a wireless LAN but also a circuit for performing frequency conversion or modulation/demodulation of a reception signal and a transmission signal.
Matsui, Hiroaki, Okada, Kazuhisa, Furuya, Ryoji
Patent | Priority | Assignee | Title |
Patent | Priority | Assignee | Title |
4717894, | Oct 23 1986 | Agilent Technologies Inc | Calibration of vector modulators using a scalar detector |
6763227, | Nov 07 2001 | Texas Instruments Incorporated | Systems and methods for modulator calibration |
7039382, | May 15 2001 | AVAGO TECHNOLOGIES GENERAL IP SINGAPORE PTE LTD | DC offset calibration for a radio transceiver mixer |
7259569, | Jan 05 2005 | Samsung Electronics Co., Ltd. | Calibration circuit and method thereof |
7496343, | Feb 15 2002 | AVAGO TECHNOLOGIES GENERAL IP SINGAPORE PTE LTD | Programmable mixer for reducing local oscillator feedthrough and radio applications thereof |
7660563, | Sep 26 2005 | MUFG UNION BANK, N A | Apparatus and method for calibrating mixer offset |
EP1011192, | |||
JP11205401, | |||
JP2003125014, | |||
JP5327682, | |||
JP7202961, | |||
WO57545, |
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